Antihunt electrical measuring system



Jan. 17, 1950 A. J. HORNFECK 2,494,876

ANTIHUNT ELECTRICAL MEASURING SYSTEM Filed Oct. 18, 1945 5 Shuts-Sheet 1 Jmaentor ANTHONY' .1. HORNFECK WO M M/ WM (Ittorneg FIG. I.

Jan. 17, 1950 A. J. HORNFECK 2,494,876

ANTIHUNT ELECTRICAL MEASURING SYSTEM Filed Oct. 18, 1943 5 Sheets-Sheet 2 FlG.6 FIG. 4

L 82 a 83 9 FIG. 5.

FIG. 7.

Zhwentor ANTHONY J. HQRN FECK Jan. 17, 1950 A. J. HORNFECK 2,494,375

ANTIHUNT ELECTRICAL MEASURING SYSTEM Filed Oct. 18, 1943 5 Sheets-Sheet 3 Isnnentor ANTHONY J. HORNFECK Jan. 17, 1950 r A. J. HORNFECK 2,494,876

' ANTIHUNT ELECTRICAL MEASURING SYSTEM Filed Oct. 18, 1943 5 Sheets-Sheet 5 V T. AMPLIFIER l STANDARDIZED DC. VOLTAGE SOURCE ANTI HUNT/ CIRCUlT 0.0. INPUT F|(5, H

AMA l vvv Zmnentor ANTHONY J. HORNFECK FIG. poz g u SUPPLY 744 Mo/ 19M attorney Patented Jan. 17, 1950 AN TIHUNT ELECTRICAL MEASURING SYSTEM Anthony J. Hornfeck, Cleveland Heights, Ohio,

assignor to Bailey Meter Company, a corporation of Delaware Application October 18, 1943, Serial No. 506,632

12 Claims.

This invention relates to a system for measuring and/or controlling the magnitude of a variable, such as temperature, pressure, rate of fluid flow, position or displacement, although the variable may be of any chemical, physical, electrical, thermal or other characteristic.

In accordance with my invention variations in a variable quantity, quality or condition are translated into variations in an electrical effect, and this eifect is then amplified solely through electrical means until sufilcient power is available for doing useful work, such as moving an indicator or other exhibiting means, or for regulating the rate of application of an agent contributing to the production or maintenance of the variable.

In devices of the same general type at present known wherein variations in the variable are translated into variations in an electrical efiect the necessary amplification is done, at least in part, by mechanical means. There are, therefore, variations in magnitude of the variable translated into variations in an electrical effect which is then translated into a corresponding mechanical movement, such as the deflection of a galvanometer, and thence usually the mechanical movement is translated back into an electrical effect for operating the exhibiting or control device. Because of the small power available in the first electrical efiect such devices usually operate on a periodic or step by step principle. That is to say, upon a change in the variable the exhibiting or control device is not continuously operated in correspondence with such change or changes, but periodically by means of a feeler mechanism an exhibiting or control device is changed an amount corresponding to the amount of change in the variable during succeeding increments of time. Such step by step and feeler mechanisms are well known in the art.

It is evident that such devices are necessarily complicated and delicate and do not correctly exhibit the variable during transient periods. My invention is particularly concerned with the elimination of all mechanical movements between the sensitive device and the exhibiting or control device, leading to simplification and removal of the usual time delay, so that the device accurately exhibits the magnitude of the variable even during transient periods. It is evident that many ancillary advantages will follow, among which may be mentioned as obvious the elimination of wear of mechanical parts and the elimination of the necessity of periodic inspection and adjustment to correct for inaccuracies occasioned by mechanical wear.

The great majority of low level D.-C. measuring systems, such as thermocouple potentiometer recorders, use a galvanometer for detecting or measuring the D.-C. input. The galvanometer is a relatively fragile device and is affected by mechanical vibration and easily damaged by overload or mishandling. Vacuum tube or electron amplifiers for low D.-C. voltages have not been successful because of instability and drift. The particular object of the present invention is to provide apparatus and a new method of detecting and amplifying small D.-C. voltages or currents. The present method involves the use of a device (which I term a reactor converter) which converts a D.-C. signal of reversing polarity into a greatly amplified A.-C. signal of reversing phase. The apparatus includes a pair of iron core reactors and has all of the sensitivity of a galvanometer as well as the sturdiness of a transformer. ,There are no delicate moving mechanical parts to wear out or to be damaged.

The reactor converter produces a greatly amplified A.-C. output signal of reversing phase which is supplied to a phase sensitive electronic amplifier and motor control circuit. In this way a thermocouple, having an output of only a few millivolts, is used to position a reversing motor with no intermediate mechanical or moving parts. The reversing motor may position an indicator or recorder and at the same time a potentiometer for balancing the system, which may be of the null type. I

A particular object of my present invention is in the provision of an anti-hunt electrical measuring system.

This application constitutes a continuation-inpart of my copending application Serial No. 453,486, filed August 3, 1942 to which reference may be made for a more detailed description of the basic circuits to which my present invention is applied.

Fig. 1 is a wiring diagram including speed voltage feed-back from an auxiliary slide wire.

Fig. 2 illustrates a slide wire assembly.

Fig. 3 illustrates a D.-C. measuring circuit with non-linear inverse feed-back.

Fig. 4 is a graph in connection with Fig. 3.

Fig. 5 shows a modification of Fig. 3.

Figs. 6 and 7 are graphs in connection with Fig. 5.

Fig. 8 illustrates a portion of the circuit of a D.-C. measuring system embodying a stabilizing feedback from motor control reactors.

Fig. 9 is a graph of operation in connection with Fig. 8.

Fig. 10 shows a saturaole core reactor construction for Fig. 8.

Fig. 11 illustrates a D.-C. measuring system using photoelectric-galvanometer converter with speed voltage feed back from an auxiliary slide wire.

Fig. 12 is a modification 01' a portion of Fig. 11.

Fig. 1 is a diagrammatic representation of a high speed direct current recorder circuit using a speed-voltage feedback from an auxiliary slidewire. A thermocouple 21 is sensitive to the temperature of afurnace 43 supplied with fuel for combustion through a pipe 44 under the control of a regulating valve 45. Basic measuring circuit for the thermocouple 21 is described in my copending application Serial No. 453,486 and includes a reactor-converter l and amplifier I 6 for controlling a reversing motor I8A which is adapted to position a recording pen 2!.

In general the action of the reactor converter [5 is one of changing a direct current signal of given polarity into a greatly amplified alternating current signal of given phase; and the ability of reversing the phase of the alternating current signal 180 when the polarity or sign of the direct current signal is reversed.

In a circuit of this general type difllculty may be encountered because oi the motor hunting about the balance point. This instability may be caused by the inductive time lag in the reactor unit which produces an inertia or flywheel effect. In my copending application I provide a feedback to the D.-C. input circuit in such a direction as to oppose the input. The effect of this feedback is to decrease the time lag in the converter and to produce a momentary shift in the zero input point so that the D.-C. input circuit will be balanced before the true balance is reached.

The anti-hunt circuit of Fig. 1 comprises broadly an inductive coupling device M whose primary is supplied with variable direct current from the potentiometer circuit source 15 and whose secondary provides a feedback to the input direct current saturating winding of the reactor converter 15. Current and voltage in the primary circuit is controlled by the position of a contact arm 19 along a slide wire S; said contact arm positioned by the motor I8A along with the slide wire contact 23, the indicator 24 and pilot 54.

Th inductive coupling device M is in construction in the nature of a coupling transformer, although it is inductively coupling two direct current circuits. The arrangement is such that when the voltage and current in the primary circuit is varied (by the motor iBA) the voltage and current in the output circuit is also varied. In a steady state there is no inductive transfer effect between the primary and secondary. In other words, a variation in the secondary circuit is produced only upon change in voltage or current of the primary, is therefore proportional to rate of change in the primary, and consequently proportional to rate of speed of the motor MA.

The secondary voltage developed by the coupling device M is proportional to the speed at which the motor [8A is positioning the slide wire contact S. A portion of this speed voltage is supplied in opposition to the unbalanced voltage developed in the thermocouple-potentiometer circuit. The eiiect is to produce a dynamic or running balance point ahead of the true static balance point. This tends to slow down or temporarily stop the motor so as to prevent overshooting and hunting and permits much faster speed than would otherwise be possible.

An auxiliary slide wire 8, which may be mounted on the same hub as the measuring slide wire 23, is supplied with direct current voltage from the source 15. The voltage then supplied to the primary of the coupling device M depends upon the position oi the contact [9 relative to the slide wire S, while the secondary voltage is proportional to the rate of change of contact position; consequently is proportional to the motor speed. Such an arrangement of slide wires is illustrated in Fig. 2 wherein the motor rotor 5 may be provided with necessary gear reduction and drives an insulating hub 16 carrying on its periphery the slide wires S and 23; as well as a cam 11. The indicator arm 24 may be positioned from the cam 11, while contacts 18, I9 engage the movable slide wires 23 and S respectively.

The action of this speed voltage feedback may be mathematically explained as follows:

If R1 is large compared with Li and M, the voltages -ac nsta t 't d RIRZ o n zposiionmg spec and e2=i2T=a constant at speed In Fig. 3 I illustrate a direct current measuring system, including a non-linear inverse feedback. The purpose of this circuit is to limit the build-up of the unbalanced current (or voltage) supplied from the potentiometer measuring circuit to the reactor converter l5. This is to prevent a shift in the null point or possible damage to the reactor converter caused by a rapid and large change. The feedback also has the eifect of increasing the stability of the system.

A non-linear resistor 8| may be of the silicon carbide type which has a very high resistance when low voltage is applied across it,- but whose resistance decreases at a very rapid rate as the voltage is increased. For small changes the feedback will be negligible and no appreciable reduction in sensitivity will result. For larger changes the feedback will become much greater and will limit the input current to the converter to a safe value, since the voltage ex is always in such a direction as to oppose the input. Fig. 4 expresses this graphically.

Copper oxide or a similar type of polarizing resistor may be used in place of silicon carbide. To make such a unit independent of polarity it is necessary to use two components as graphically indicated in Figs. 5, 6 and '7.

Fig. 8 represents a further embodiment of my invention in connection with a part of a complete circuit. For example, referring to Fig. 3, I have indicated terminals 84, 85, 86 between the motor control tubes and the saturable reactor control of the capacitor-run motor [8A. In Fig. 8 I omit, for the sake of simplicity, a duplication of the potentiometer circuit as well as the reactor converter l5 and amplifier I5. I show a feedback arrangement to the D.-C. input of the reactor converter I5 from the saturable core reactors which are controlling the motor lllA responsive to an amplifier l6 and motor control tubes 36, 31.

To this circuit has been added a stabilizing feedback including two coils 81, 88 wound around the center leg of the motor control reactors 50 and 5| in addition to the saturating D.-C. winding 84 or 85'. These coils 81, 88 carry direct current and are connected in series so that the induced voltages are additive. A portion of this total volt age is applied to the input circuit in such a direction as to accelerate the change. Assuming that reactor X is saturated and that the motor is driving the potentiometer contact to balance from one direction. The D.-C. current in X will begin to decrease as the input to the reactor converter decreases while the D.-C. current in Y will begin to increase. This change of current in X and Y will induce voltages in the windings 81, 88 of X and Y in accordance with the equation:

where M is the mutual inductance and i is the D.-C. current.

The total voltage applied to the input circuit will be proportional to the sum of the two induced voltages:

di, ef-- K (M (F and will oppose the original unbalance from the measuring circuit. This will tend to slow down or stop the motor before the true balance is reached and will prevent excessive overshooting or hunting. On the other hand, if the system is assumed to be in balance and a small change in the D.-C. input voltage occurs, the induced voltage will be in such a direction as to supply a feedback voltage which will aid the original unbalance. This will accelerate the motor faster than would otherwise occur and the speed of response of the system will be increased.

The arrangement is similar in theory to that described in connection with the inductive coupling device M of Fig. 1. Winding 84' carries direct current saturating control from the amplifier. Winding 81 normally carries no current. Upon change in direct current value through the winding 84' there is induced in the winding 81 a direct current whose magnitude and polarity is determined by the direction and magnitude of change in the voltage through the winding 84. Under-a steady state of voltage in the winding 84 there is no direct current voltage in the winding 81. It is only upon change in voltage in the winding 84' that a voltage is induced in the winding 81, and it is induced in a direction depending upon the direction of change, i. e. whether the voltage inv 84' has increased or decreased. The magnitude of the induced voltage in the winding 81 is determined by the rate of change in voltage in the winding 84'.

The direct current voltages in the circuit including the windings 81, 88 in series are additive. When the motor I8A is to be rotated, then the saturating current in winding 84' will increase (for example) while the saturating direct current in the winding decreases. The increase in saturating voltage in 34' produces a voltage in 81, while the decrease in saturating current in 85 produces a voltage in winding 88.

It will be noted that this feedback couples the output circuit with the input circuit in a regenerative fashion somewhat similar to certain types of vacuum tube oscillators. If the feedback voltage is of sufficient magnitude, self-oscillations can be induced in the system which will keep the motor constantly in oscillation even at balance conditions. By proper adjustment this oscillation can be held at a small enough amplitude so as to just take up the backlash in the gears and not enough to cause any motion of the potentiometer contact arm on the slide wire. By keeping the motor rotor quivering constantly the sensitivity of the system is greatly increased, since static friction of the motor bearing does not have to be overcome before the motor begins to position the potentiometer slide wire. The slightest unbalance of the measuring circuit will unbalance the rotor oscillations so that there will be an average motion of the potentiometer slide wire to rebalance the system. This action is clearly shown in Fig. 9. The construction of the saturable core reactor X (or reactor Y) may be as illustrated in Fig. 10 comprising a three legged core having the A.-C. output winding comprising two coils on the outer leg connected in series and with the D.-C. input coil 84 and the feedback coil 81 on the center leg.

The feedback circuits illustrated in Figs. 1-10 inclusive, and described in connection therewith, are not limited to use in connection with the reactor converter l5. Fig. 11 shows a circuit using a vacuum tube amplifier, motor control circuit and feedback system such as is shown in Fig. 1 but employing a photosensitive A.-C.-D.-C. converter.

Referring to Fig. 11, at balance equal light falls on the photo tubes P1 and P2 so that the bridge circuit (of which these tubes are a part) is balanced. E1 and E2 are zero and the motor remains stationary. If a change in D.-C. input occurs the measuring circuit becomes temporarily unbalanced and a voltage input to the galvanometer G causes its mirror to deflect. As a result the light falling on the photo tubes is unbalanced and a pulsating voltage appears across the output resistor R1. Since the vacuum tube amplifier is coupled through the condenser 89 only the alternating component of the pulsating voltage E1 will appear across R2. This voltage is amplified and selectively controls reactors T and U to cause the motor IM to rotate and rebalance the measuring circuit. Here, as in Fig. 1, I provide a direct current measuring system incorporating speed voltage feedback from an auxiliary slide wire and in connection with a photo-electric-galvanometer converter.

I have not felt it necessary to further complicate the drawings by duplicating the indicating or recording mechanism in the later described .figures, although it will be appreciated that a primary purpose of the circuit is to measure and provide a visual indication, as well as perhaps a permanent record, of the temperature or other variable which has produced the direct current, or change in direct current, which is to be measured. Furthermore, of course the motors l8 and [8a may be used to control as has been described in connection with earlier figures of the drawing. Furthermore, the circuit arrangements are not limited to the use of the capacitor-run type of motor, but may be equally as well adapted to onposed field motors, direct current motors, shaded pole motors, etc. The principal feature, however, of this application lies in the anti-hunting feedback circuits which are useful in numerous measuring or controlling total circuits.

In Fig. 12 I. show a modification of the total circuit illustrated in Fig. 11 wherein the portions of Fig. 16 below and to the left of terminals 90,

SI and mechanical connections 92, 93 are not duplicated in Fig. 1 There is a somewhat simplified recording system in which the amount of light falling on photo cells P1 and P2 controls the flow of current through R1 and R: and consequently the grid voltage of tubes V1 and V2. If more light falls on P1 than on P2 then V1 is made more conducting than Va and reactor T passes current to actuate the motor lfla. This circuit differs from that of Fig. 11 in that direct current voltage is applied to the anodes of the photo tubes P1 and P: and to the plates of the amplifying tubes V1 and V: which control the saturable reactors T and U.

It will be apparent that I have illustrated and described certain preferred embodiments of my invention but that I am not to be limited thereto as many substitutions of equivalent apparatus and circuits may be used without destroying the intent and novelty of my invention.

Certain features of my present invention, disclosed but not claimed herein, are disclosed and claimed in my copending divisional application Serial No. 93,870 filed May 18, 1949.

What I claim as new, and desire to secure by Letters Patent of the United States, is:

1. A balanceable electrical network including in combination, a converter having means for converting a low-level direct current signal of reversible polarity into an amplified alternating current signal of reversible phase, a source of al ternatlng current for the converter, a source of lowlevel direct current, electronic means selectively sensitive to the alternating current output signal of reversible phase, a reversible electric motor energized from the output circuits of said electronic means, means positioned by said electric motor tor'educe said direct current signal, and electrical induction means connected in the output circuits of said electronic means and introducing a voltage into the input of said converter for accelerating changes in said input signal.

2. A balanceable electrical network including in combination, a converter having means for converting a low-level direct current signal of reversible polarity into an amplified alternating current signal of reversible phase, a source of alternating current for the converter, a circuit for supplying to said converter a lowlevel direct current signal varying in accordance with changes in the magnitude of a condition, electronic means selectively sensitive to the alternating current output signal of reversible phase, a reversible electric motor selectively actuated by said electronic means, means positioned by said electric motor to balance said network following 8 an unbalance thereof caused by variation in said direct current signal, a winding connected in the output circuit of each of said electronic means and coupled inductively to a second winding, and means connecting said second windings across a resistor in said direct current signal circuit.

3. The combination of claim 2 wherein said second windings are connected in series aiding across said resistor.

4. A balanceable electrical network including in combination, a reactor converter having means for converting a low-level direct current signal of reversible polarity into an amplified alternating current signal of reversible phase, a source of alternating current for the converter, 9. source of low-level direct current, electronic means selectively sensitive to the alternating current output signal of reversible phase, 'a reversible electric motor, means positioned by said electric motor to balance said network following an unbalance thereof caused by variation in said direct current signal, saturable core reactor means selectively made effective by said electronic means for controlling direction and speed of rotation of said motor, and electrical means including windings magnetically coupled with windings of said saturable core reactor means for modifying said direct current low level signal.

5. A motor control circuit including a pair of similar saturable core reactors for selectively controlling direction and speed of motor rotation, each reactor having an alternating current winding in the motor circuit, a direct current saturating control winding and a second direct current winding, means connecting said second windings to be algebraically additive, means connecting the output of said second windings to be regeneratively effective in control of said motor, a source of variable voltage direct current for said saturating control windings, said second windings having direct current voltage and/or current induced therein only upon change in voltage in said saturating windings but electrically dead during steady state of current or voltage in the saturating windings.

6. In combination, a capacitor-run alternating current motor having two winding ninety electrical degrees apart and a capacitor, rotation of said motor occurring in desired direction when one of said windings is energized directly across a source of alternating current and simultaneously the other winding is connected in series with the capacitor across said source, a source of alternating current for said windings, saturable core reactor means directionally controlling energization of said windings, said reactors having alternating current impedance windings connected in the motor circuit, direct current saturating control windings for said reactors, other normally deenergized direct current windings for the reactors energized only upon change in volt-- age in said saturating windings, and means conductively associating the saturating and other direct current windings.

7. The combination of claim 6 including a direct current input source for said saturating com trol windings, voltage induced in said other direct current windings modifying said direct cunrent input.

8. A balanceable electrical network including a potentiometer for balancing the network, a motor adapted to vary the potentiometer, saturable core reactor means directionally controlling motor rotation, alternating current controlled windings on said saturable core reactor means connected in said motor circuit, direct current saturating control means for the reactors, and other direct current windings for said reactors inductively energized only upon change in voltage in said saturating windings and arranged to modify the voltage in said network during unbalance of the network.

9. A saturable core reactor comprising a three leg core member having a pair of alternating current controlled windings connected in series one on each of the two outer legs, a direct current saturating control winding around the center leg, a source of pulsating direct current for said saturating winding produced by half wave rectiflcation of alternating current, a condenser across said saturating winding, a second direct current winding around the center leg inductively energized only during change in voltage in said saturating winding, and means connecting the output of said second direct current winding to oppose said source.

10. A system for measuring the magnitude of a condition comprising, in combination, means for producing a D.-C. signal varying in direction and amplitude with changes in the condition, a reversible motor for regulating said D.-C. signal, separate circuits connected to a source of A.-C. for energizing said motor to operate in one direc-- tion or the other, means responsive to said D.-C. signal for controlling the energizing of said separate circuits, said last mentioned means including saturable core reactors, each having an A.-C. winding connected in one of said separate circuits and a D.-C. winding energized in response to said signal, and means including windings magnetically coupled to said D.-C. windings for introducing into the system an electromotive force modifying said D.-C. signal.

11. The system of claim in which said signal responsive means includes means for increasing the current in the D.-C. winding of one of said reactors on a variation of the D.-C. signal in one direction and increasing the current in the D.-C. winding of the other of said reactors on a variation of the D.-C. signal in the opposite direction, and said last mentioned means introduces the electromotive force from the magnetically coupled windings into the system for accelerating changes in said input signal.

12. A balanceable electrical network including in combination, a converter having means for converting a low-level direct current signal of reversible polarity into an amplified alternating current signal of reversible phase, a source oi alternating current for the converter, a source of low-level direct current, electronic means selectively sensitive to the alternating current output signal of reversible phase, a capacitor-run motor having two windings electrical degrees apart and a. capacitor, rotation of said motor effected in desired direction when one of said windings is energized directly across an alternating current source and the other of said windings is simultaneously energized across said source in series with said capacitor, said motor selectively directionally actuated by said electronic means, means positioned by said motor to balance said network following an unbalance thereof caused by variation in said direct current signal, and electrical means including inductively coupled windings, one connected in an output circuit of said electronic means and the other connected to the input circuit of said converter, for modifying said input signal.

ANTHONY J. HORNFECK.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,955,322 Brown Apr. 17, 1934 2,025,749 I Hubbard Dec. 31, 1935 2,109,222 Ryder Feb. 22, 1938 2,113,164 Williams Apr. 5, 1938 2,113,436 Williams Apr. 5, 1938 2,261,083 Harrison Oct. 28, 1941 2,276,816 Bagno Mar. 17, 1942 2,277,849 Fitzgerald Mar. 31, 1942 2,278,151 Runaldue Mar. 31, 1942 2,310,955 Homfeck Feb. 16, 1943 2,333,393 Ryder Nov. 2, 1943 2,376,599 Jones May 22, 1945 r 2,401,168 Kronenberger May 28, 1946 FOREIGN PATENTS Number Country Date r 489,271 Great Britain July' 22, 1938 

